Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 Rickettsia actin-based motility occurs in distinct phases mediated by different actin nucleators.

Literature DB >> 24361066

Rickettsia actin-based motility occurs in distinct phases mediated by different actin nucleators.

Shawna C O Reed¹, Rebecca L Lamason², Viviana I Risca³, Emma Abernathy⁴, Matthew D Welch⁵.

Abstract

Many intracellular bacterial pathogens undergo actin-based motility to promote cell-cell spread during infection [1]. For each pathogen, motility was assumed to be driven by a single actin polymerization pathway. Curiously, spotted fever group Rickettsia differ from other pathogens in possessing two actin-polymerizing proteins. RickA, an activator of the host Arp2/3 complex, was initially proposed to drive motility [2, 3]. Sca2, a mimic of host formins [4, 5], was later shown to be required for motility [6]. Whether and how their activities are coordinated has remained unclear. Here, we show that each protein directs an independent mode of Rickettsia parkeri motility at different times during infection. Early after invasion, motility is slow and meandering, generating short, curved actin tails that are enriched with Arp2/3 complex and cofilin. Early motility requires RickA and Arp2/3 complex and is correlated with transient RickA localization to the bacterial pole. Later in infection, motility is faster and directionally persistent, resulting in long, straight actin tails. Late motility is independent of Arp2/3 complex and RickA and requires Sca2, which accumulates at the bacterial pole. Both motility pathways facilitate cell-to-cell spread. The ability to exploit two actin assembly pathways may allow Rickettsia to establish an intracellular niche and spread between diverse cells throughout a prolonged infection.

Entities: CellLine Chemical Disease Gene Species

Mesh：

Substances：

Year: 2013 PMID： 24361066 PMCID： PMC3951146 DOI： 10.1016/j.cub.2013.11.025

Source DB: PubMed Journal: Curr Biol ISSN： 0960-9822 Impact factor: 10.834

34 in total

1. Rickettsia parkeri rickettsiosis and its clinical distinction from Rocky Mountain spotted fever.

Authors: Christopher D Paddock; Richard W Finley; Cynthia S Wright; Howard N Robinson; Barbara J Schrodt; Carole C Lane; Okechukwu Ekenna; Mitchell A Blass; Cynthia L Tamminga; Christopher A Ohl; Susan L F McLellan; Jerome Goddard; Robert C Holman; John J Openshaw; John W Sumner; Sherif R Zaki; Marina E Eremeeva
Journal: Clin Infect Dis Date: 2008-11-01 Impact factor: 9.079

2. Polar localization of the autotransporter family of large bacterial virulence proteins.

Authors: Sumita Jain; Peter van Ulsen; Inga Benz; M Alexander Schmidt; Rachel Fernandez; Jan Tommassen; Marcia B Goldberg
Journal: J Bacteriol Date: 2006-07 Impact factor: 3.490

3. Dynamics of actin-based movement by Rickettsia rickettsii in vero cells.

Authors: R A Heinzen; S S Grieshaber; L S Van Kirk; C J Devin
Journal: Infect Immun Date: 1999-08 Impact factor: 3.441

4. The 5' untranslated region-mediated enhancement of intracellular listeriolysin O production is required for Listeria monocytogenes pathogenicity.

Authors: Aimee Shen; Darren E Higgins
Journal: Mol Microbiol Date: 2005-09 Impact factor: 3.501

5. Requirement for formin-induced actin polymerization during spread of Shigella flexneri.

Authors: Jason E Heindl; Indrani Saran; Chae-ryun Yi; Cammie F Lesser; Marcia B Goldberg
Journal: Infect Immun Date: 2009-10-19 Impact factor: 3.441

6. Mariner-based transposon mutagenesis of Rickettsia prowazekii.

Authors: Zhi-Mei Liu; Aimee M Tucker; Lonnie O Driskell; David O Wood
Journal: Appl Environ Microbiol Date: 2007-08-24 Impact factor: 4.792

Review 7. Arp2/3-mediated actin-based motility: a tail of pathogen abuse.

Authors: Matthew D Welch; Michael Way
Journal: Cell Host Microbe Date: 2013-09-11 Impact factor: 21.023

8. Listeria monocytogenes ActA-mediated escape from autophagic recognition.

Authors: Yuko Yoshikawa; Michinaga Ogawa; Torsten Hain; Mitsutaka Yoshida; Makoto Fukumatsu; Minsoo Kim; Hitomi Mimuro; Ichiro Nakagawa; Toru Yanagawa; Tetsuro Ishii; Akira Kakizuka; Elizabeth Sztul; Trinad Chakraborty; Chihiro Sasakawa
Journal: Nat Cell Biol Date: 2009-09-13 Impact factor: 28.824

9. Characterization of two classes of small molecule inhibitors of Arp2/3 complex.

Authors: B J Nolen; N Tomasevic; A Russell; D W Pierce; Z Jia; C D McCormick; J Hartman; R Sakowicz; T D Pollard
Journal: Nature Date: 2009-08-02 Impact factor: 49.962

10. Repulsion of superinfecting virions: a mechanism for rapid virus spread.

Authors: Virginie Doceul; Michael Hollinshead; Lonneke van der Linden; Geoffrey L Smith
Journal: Science Date: 2010-01-21 Impact factor: 47.728

49 in total

Review 1. Bacterial nucleators: actin' on actin.

Authors: Joana N Bugalhão; Luís Jaime Mota; Irina S Franco
Journal: Pathog Dis Date: 2015-09-27 Impact factor: 3.166

Review 2. Global treadmilling coordinates actin turnover and controls the size of actin networks.

Authors: Marie-France Carlier; Shashank Shekhar
Journal: Nat Rev Mol Cell Biol Date: 2017-03-01 Impact factor: 94.444

Review 3. Cells within cells: Rickettsiales and the obligate intracellular bacterial lifestyle.

Authors: Jeanne Salje
Journal: Nat Rev Microbiol Date: 2021-02-09 Impact factor: 60.633

4. Actin-based motility of bacterial pathogens: mechanistic diversity and its impact on virulence.

Authors: Julie E Choe; Matthew D Welch
Journal: Pathog Dis Date: 2016-09-20 Impact factor: 3.166

Review 5. Engineering of obligate intracellular bacteria: progress, challenges and paradigms.

Authors: Erin E McClure; Adela S Oliva Chávez; Dana K Shaw; Jason A Carlyon; Roman R Ganta; Susan M Noh; David O Wood; Patrik M Bavoil; Kelly A Brayton; Juan J Martinez; Jere W McBride; Raphael H Valdivia; Ulrike G Munderloh; Joao H F Pedra
Journal: Nat Rev Microbiol Date: 2017-06-19 Impact factor: 60.633